A highly conserved family of inactivated archaeal B family DNA polymerases

   

A widespread and highly conserved family of apparently inactivated derivatives of archaeal B-family DNA polymerases is described. Phylogenetic analysis shows that the inactivated forms comprise a distinct clade among archaeal B-family polymerases and that, within this clade, Euryarchaea and Crenarchaea are clearly separated from each other and from a small group of bacterial homologs. These findings are compatible with an ancient duplication of the DNA polymerase gene followed by inactivation and parallel loss in some of the lineages although contribution of horizontal gene transfer cannot be ruled out. The inactivated derivative of the archaeal DNA polymerase could form a complex with the active paralog and play a structural role in DNA replication.     

Strand annealing and terminal transferase activities of a B-family DNA polymerase

DNA replication polymerases have the inherent ability to faithfully and rapidly copy a DNA template according to precise Watson-Crick base pairing. The primary B-family DNA replication polymerase (Dpo1) in the hyperthermophilic archaeon, Sulfolobus solfataricus, is shown here to possess a remarkable DNA stabilizing ability for maintaining weak base pairing interactions to facilitate primer extension. This thermal stabilization by Dpo1 allowed for template-directed synthesis at temperatures more than 30 °C above the melting temperature of naked DNA. Surprisingly, Dpo1 also displays a competing terminal deoxynucleotide transferase (TdT) activity unlike any other B-family DNA polymerase. Dpo1 is shown to elongate single-stranded DNA in template-dependent and template-independent manners. Experiments with different homopolymeric templates indicate that initial deoxyribonucleotide incorporation is complementary to the template. Rate-limiting steps that include looping back and annealing to the template allow for a unique template-dependent terminal transferase activity. The multiple activities of this unique B-family DNA polymerase make this enzyme an essential component for DNA replication and DNA repair for the maintenance of the archaeal genome at high temperatures.     

Structures of phi29 DNA polymerase complexed with substrate: the mechanism of translocation in B-family polymerases

Replicative DNA polymerases (DNAPs) move along template DNA in a processive manner. The structural basis of the mechanism of translocation has been better studied in the A-family of polymerases than in the B-family of replicative polymerases. To address this issue, we have determined the X-ray crystal structures of phi29 DNAP, a member of the protein-primed subgroup of the B-family of polymerases, complexed with primer-template DNA in the presence or absence of the incoming nucleoside triphosphate, the pre- and post-translocated states, respectively. Comparison of these structures reveals a mechanism of translocation that appears to be facilitated by the coordinated movement of two conserved tyrosine residues into the insertion site. This differs from the mechanism employed by the A-family polymerases, in which a conserved tyrosine moves into the templating and insertion sites during the translocation step. Polymerases from the two families also interact with downstream single-stranded template DNA in very different ways.     

Switching between polymerase and exonuclease sites in DNA polymerase ε

The balance between exonuclease and polymerase activities promotes DNA synthesis over degradation when nucleotides are correctly added to the new strand by replicative B-family polymerases. Misincorporations shift the balance toward the exonuclease site, and the balance tips back in favor of DNA synthesis when the incorrect nucleotides have been removed. Most B-family DNA polymerases have an extended β-hairpin loop that appears to be important for switching from the exonuclease site to the polymerase site, a process that affects fidelity of the DNA polymerase. Here, we show that DNA polymerase ε can switch between the polymerase site and exonuclease site in a processive manner despite the absence of an extended β-hairpin loop. K967 and R988 are two conserved amino acids in the palm and thumb domain that interact with bases on the primer strand in the minor groove at positions n−2 and n−4/n−5, respectively. DNA polymerase ε depends on both K967 and R988 to stabilize the 3′-terminus of the DNA within the polymerase site and on R988 to processively switch between the exonuclease and polymerase sites. Based on a structural alignment with DNA polymerase δ, we propose that arginines corresponding to R988 might have a similar function in other B-family polymerases.     

Translesion synthesis across abasic lesions by human B-family and Y-family DNA polymerases α, δ, η, ι, κ, and REV1

Abasic (apurinic/apyrimidinic, AP) sites are the most common DNA lesions formed in cells, induce severe blocks to DNA replication, and are highly mutagenic. Human Y-family translesion DNA polymerases (pols) such as pols η, ι, κ, and REV1 have been suggested to play roles in replicative bypass across many DNA lesions where B-family replicative pols stall, but their individual catalytic functions in AP site bypass are not well understood. In this study, oligonucleotides containing a synthetic abasic lesion (tetrahydrofuran analogue) were compared for catalytic efficiency and base selectivity with human Y-family pols η, ι, κ, and REV1 and B-family pols α and δ. Pol η and pol δ/proliferating cell nuclear antigen (PCNA) copied past AP sites quite effectively and generated products ranging from one-base to full-length extension. Pol ι and REV1 readily incorporated one base opposite AP sites but then stopped. Pols κ and α were severely blocked at AP sites. Pol η preferentially inserted T and A; pol ι inserted T, G, and A; pol κ inserted C and A; REV1 preferentially inserted C opposite AP sites. The B-family pols α and δ/PCNA preferentially inserted A (85% and 58%, respectively) consonant with the A-rule hypothesis. Pols η and δ/PCNA were much more efficient in next-base extension, preferably from A positioned opposite an AP site, than pol κ. These results suggest that AP sites might be bypassed with moderate efficiency by single B- and Y-family pols or combinations, possibly by REV1 and pols ι, η, and δ/PCNA at the insertion step opposite the lesion and by pols η and δ/PCNA at the subsequent extension step. The patterns of the base preferences of human B-family and Y-family pols in both insertion and extension are pertinent to some of the mutagenesis events induced by AP lesions in human cells.     

Secondary structure of condensed DNA. wide-angle, small-angle x-ray scattering and circular dichroism

Ethanol precipitated DNA shows a CD spectrum of the +psi-type which is similar to that of DNA in the A-form. DNA condensed with cetyl-trimethylammonium-bromide shows, depending on the condensation velocity, a CD spectrum of the -psi-type, or a CD spectrum only slightly modified from that of DNA in solution. The first spectrum is similar to that of DNA in the C-form, and the second one, to that of DNA in the B-form. Using large-angle X-ray scattering of the three DNA condensates and comparing them with the scattering curves calculated from the atom coordinates for the A-, B-, and C-form of DNA it is shown that the secondary structure of the DNA belongs in all three cases to the B-family. It follows from this result that the secondary structure of DNA alone does not determine the type of CD spectrum. The CD spectrum of condensed DNA is essentially determined by the supramolecular structures of the partially crystalline DNA condensates. These supramolecular structures can be demonstrated by the small-angle X-ray diagrams. The condensation of DNA by ethanol and cetyl-trimethylammonium-bromide proceeds in the form of a partial crystallization of the DNA.     

Structural basis for inhibition of DNA replication by aphidicolin

Natural tetracyclic diterpenoid aphidicolin is a potent and specific inhibitor of B-family DNA polymerases, haltering replication and possessing a strong antimitotic activity in human cancer cell lines. Clinical trials revealed limitations of aphidicolin as an antitumor drug because of its low solubility and fast clearance from human plasma. The absence of structural information hampered the improvement of aphidicolin-like inhibitors: more than 50 modifications have been generated so far, but all have lost the inhibitory and antitumor properties. Here we report the crystal structure of the catalytic core of human DNA polymerase α (Pol α) in the ternary complex with an RNA-primed DNA template and aphidicolin. The inhibitor blocks binding of dCTP by docking at the Pol α active site and by rotating the template guanine. The structure provides a plausible mechanism for the selectivity of aphidicolin incorporation opposite template guanine and explains why previous modifications of aphidicolin failed to improve its affinity for Pol α. With new structural information, aphidicolin becomes an attractive lead compound for the design of novel derivatives with enhanced inhibitory properties for B-family DNA polymerases.     

Structural forms and transitions of poly(dG-dC) with Cd(II), Ag(I) and NaNO3

Infrared spectroscopy was used to study the structures and transitions in hydrated gels of double-helical poly(dG-dC) complexed with the metal carcinogens Cd(II) and Ag(I). For one Cd(II) per ten nucleotides (r = 0.1), the B structure was stable at high and moderate hydrations with D2O and the B and Z structures coexisted at low hydrations. For poly(dG-dC) with Cd(II) at r = 0.2 to 0.35, the Z structure was stable at high hydrations (94% r.h. for r = 0.2). At a given value of hydration, H2O gave a higher content of Z structure than D2O. Cd(II) most likely binds to guanine residues at N7 in both the B and Z forms of poly(dG-dC) but binding to guanine N3 can not be excluded. It is unlikely that Cd(II) binds to cytosine residues at the r values studied and the cytosine residues did not protonate at N3 as Cd(II) bound to guanine residues. Poly(dG-dC) with Ag(I) at r = 0.2 to 0.36, existed in a B-family structure which is different from the B-family structure of the type I complex of Ag(I) and calf-thymus DNA. Poly(dG-dC) with Ag(I) did not assume the Z structure at lower hydrations even though NO3- was present in the sample. Ag(I) differs from other soft-metal acids which promote the Z structure. Ag(I) most likely binds to the guanine N7 or N3 and not to cytosine residues. Cytosine residues did not protonate at N3 as Ag(I) was bound to guanine.(ABSTRACT TRUNCATED AT 250 WORDS)     

A new model for DNA containing A.T and I.C base pairs.

DNA polymers containing exclusively A.T or I.C base pairs frequently exhibit D- or E-type X-ray diffraction patterns when dried. The distribution of intensities in fiber patterns appears to demand helical structures with 7 and 7.5 bp/turn, respectively, but it is not stereochemically possible to wind a right-handed antiparallel B-family helix this tightly. It is a simple matter, however, to build a left-handed helix with 7-7.5 bp/turn by incorporating Hoogsteen pairing into a Z helix framework. X-ray intensities calculated from this novel left-handed Hoogsteen model provide as reasonable a fit to the D-DNA diffraction pattern as do intensities calculated from previously proposed right-handed 8-fold models.     

THE DNA POLYMERASE GENE OF A BROWN ALGAL VIRUS: STRUCTURE AND PHYLOGENY

We have reported the complete sequence of the DNA polymerase gene from the virus that infected a filamentous brown alga, Feldmannia sp. (FsV). The DNA polymerase gene from FsV encoded 986 amino acids and contained all the conserved motifs of 3'-5' exonuclease domains and catalytic domains found in B-family (α-like) DNA polymerases. The codons for the FsV DNA polymerase appeared to have some bias toward guanine/cytosine (G/C) in the third position. The phylogenetic analysis of the FsV DNA polymerase gene and other viral DNA polymerase genes indicated that FsV belongs to a family of algal viruses recently defined as Phycodnaviridae.     

Urea effect on Cu(2+)-induced DNA structural transitions in solution

Cu(2+) ion interaction with DNA in aqueous solutions containing urea (0-5 M) was studied by IR spectroscopy. It was shown that upon the Cu(2+) ion binding DNA transition into a compact form occurs. This transition is of positive cooperativity. We suppose that the mechanism of Cu(2+)-induced DNA compaction in solutions containing urea is not completely electrostatic. Urea addition to the DNA solution decreases the Cu(2+) ion concentration required to induce DNA compaction. As the urea content in solution rises, the binding constant of Cu(2+) ions interacting with DNA increases, going through the maximum in the case of 2 M solution; further increase of the urea content in solutions leads to decrease of the binding constant. DNA transition into the compact form under the Cu(2+) ion action is determined not only by the effects of the solution dielectric permeability but by the solvation effects; when changes of the dielectric permeability are small the solvation effects may prevail. Urea addition to the DNA solution also decreases cooperativity of the DNA compaction process. Perhaps, cooperativity of the DNA transition into the compact state depends on the ordered spatial structure of water adjacent to the macromolecule and decreases on the structure destruction.     

The existence of unique B structures in polynucleotides with alternating purine-pyrimidine sequences

The infrared spectra of the sodium salts of calf-thymus DNA, poly(dA-dC).poly(dG-dT), poly(dA-dT) and poly(dG-dC) were measured for the samples as highly hydrated, nonoriented gels. The bands from the sugar-phosphate vibrational modes show that poly(dG-dC) assumes a B-family structure which is different from the B structures of the other samples. Poly(dG-dC) most likely assumes a wrinkled B structure. The other samples retain a smooth B structure. An alternating purine-pyrimidine sequence is not a sufficient condition for the formation of wrinkled B structure in a polynucleotide.     

Computational Investigation of Locked Nucleic Acid (LNA) Nucleotides in the Active Sites of DNA Polymerases by Molecular Docking Simulations

Aptamers constitute a potential class of therapeutic molecules typically selected from a large pool of oligonucleotides against a specific target. With a scope of developing unique shorter aptamers with very high biostability and affinity, locked nucleic acid (LNA) nucleotides have been investigated as a substrate for various polymerases. Various reports showed that some thermophilic B-family DNA polymerases, particularly KOD and Phusion DNA polymerases, accepted LNA-nucleoside 5′-triphosphates as substrates. In this study, we investigated the docking of LNA nucleotides in the active sites of RB69 and KOD DNA polymerases by molecular docking simulations. The study revealed that the incoming LNA-TTP is bound in the active site of the RB69 and KOD DNA polymerases in a manner similar to that seen in the case of dTTP, and with LNA structure, there is no other option than the locked C3′-endo conformation which in fact helps better orienting within the active site.     

Three-dimensional solution structure of a DNA duplex containing the BclI restriction sequence: two-dimensional NMR studies, distance geometry calculations, and refinement by back-calculation of the NOESY spectrum

A three-dimensional solution structure for the self-complementary dodecanucleotide [d-(GCCTGATCAGGC)]2 has been determined by distance geometry with further refinements being performed after back-calculation of the NOESY spectrum. This DNA dodecamer contains the hexamer [d(TGATCA)]2 recognized and cut by the restriction endonuclease BclI, and its structure was determined in hopes of obtaining a better understanding of the sequence-specific interactions which occur between proteins and DNA. Preliminary examination of the structure indicates the structure is underwound with respect to idealized B-form DNA though some of the local structural parameters (glycosyl torsion angle and pseudorotation angle) suggest a B-family type of structure is present. This research demonstrates the requirements (resonance assignments, interproton distance measurements, distance geometry calculations, and NOESY spectra back-calculation) to generate experimentally self-consistent solution structures for short DNA sequences.     

Thermodynamics of DNA duplexes with adjacent G.A mismatches.

The sequence 5'-d(ATGAGCGAAT) forms a very stable self-complementary duplex with four G.A mismatch base pairs (underlined) out of ten total base pairs [Li et al. (1991) Proc. Natl. Acad. Sci. U.S.A. 88, 26-30]. The conformation is in the general B-family and is stabilized by base-pair hydrogen bonding of an unusual type, by favorable base dipole orientations, and by extensive purine-purine stacking at the mismatched sites. We have synthesized 13 decamers with systematic variations in the sequence above to determine how the flanking sequences, the number of G.A mismatches, and the mismatch sequence order (5'-GA-3' or 5'-AG-3') affect the duplex stability. Changing A.T to G.C base pairs in sequences flanking the mismatches stabilizes the duplexes, but only to the extent observed with B-form DNA. The sequence 5'-pyrimidine-GA-purine-3', however, is considerably more stable than 5'-purine-GA-pyrimidine-3'. The most stable sequences with two pairs of adjacent G.A mismatches have thermodynamic parameters for duplex formation that are comparable to those for fully Watson-Crick base-paired duplexes. Similar sequences with single G.A pairs are much less stable than sequences with adjacent G.A mismatches. Reversing the mismatch order from 5'-GA-3' to 5'-AG-3' results in an oligomer that does not form a duplex. These results agree with predictions from the model derived from NMR and molecular mechanics and indicate that the sequence 5'-pyrimidine-GA-purine-3' forms a stable conformational unit that fits quite well into a B-form double helix.(ABSTRACT TRUNCATED AT 250 WORDS)     

Analysis in vitro of uterine estrogen receptor conformation of young and old rats

The conformation of estrogen receptor (ER) and its in vitro transformation by RNase, Urea and ATP were analysed using the uteri of young (16 weeks) and old (92 weeks) rats. Following the digestion of ER with proteolytic enzymes like trypsin and chymotrypsin and the analysis of cleaved fragments by SDS-PAGE, similar pattern is observed in both ages. In vitro transformation of ER by RNase, Urea and ATP shows that the degree of transformation is lower in old than young. Furthermore, the transformed ER from old is less capable of binding to DNA than that from young. Thus our results show that the conformation of ER probably does not change with age, but the degree of transformation and the ability of transformed receptor to bind to DNA decrease with age.     

DNA polymerase δ and ζ switch by sharing accessory subunits of DNA polymerase δ

Translesion DNA synthesis is an important branch of the DNA damage tolerance pathway that assures genomic integrity of living organisms. The mechanisms of DNA polymerase (Pol) switches during lesion bypass are not known. Here, we show that the C-terminal domain of the Pol ζ catalytic subunit interacts with accessory subunits of replicative DNA Pol δ. We also show that, unlike other members of the human B-family of DNA polymerases, the highly conserved and similar C-terminal domains of Pol δ and Pol ζ contain a [4Fe-4S] cluster coordinated by four cysteines. Amino acid changes in Pol ζ that prevent the assembly of the [4Fe-4S] cluster abrogate Pol ζ function in UV mutagenesis. On the basis of these data, we propose that Pol switches at replication-blocking lesions occur by the exchange of the Pol δ and Pol ζ catalytic subunits on a preassembled complex of accessory proteins retained on DNA during translesion DNA synthesis.     

CC/GG contacts facilitate the B to A transition of DNA in solution

Self-complementary decadeoxynucleotides, CCGATATCGG, CCAGATCTGG, CCCTGCAGGG, GGGGGCCCCC, were designed and synthesized to estimate the A-philic free energy of CC/GG contacts. First, regions of temperature-stability of the double-stranded conformation were determined for each 10-mer. Then, circular dichroism spectra were recorded for the B-family forms at different temperatures, counter-ion concentrations and trifluoroethanol contents. A cooperative change typical of the B-A transition is observed in the CD spectra at a trifluoroethanol content specific for each duplex. The positions of half-transition points were functions not only of the nucleotide sequence but of the duplex length as well: the B to A transitions were hindered in these 10-mers in comparison with a lengthy DNA. The B-phility value was estimated to be 3 kcal/mol of 10-mer. The B-A transition point was shown to drop with an increase in the number of CC/GG contacts in a duplex. The designed 10-mers made it possible to estimate quantitatively the A-phility of CC/GG contact as compared with an average DNA: (FA-FB)CC = 0.2 Kcal/mol, (FA-FB)DNA = 0.7 Kcal/mol.     

Laser Raman identification of an interaction site on DNA for arginine containing histones in chromatin.

Comparisons of the Raman spectra of DNA, chromatin, and complexes of DNA with poly-L-arginine and N-α-acetylarginine have been made. Both in native chromatin and in complexes of DNA with the arginine derivatives there is a marked decreased in the Raman intensity of the 1490±2 cm^?1 band due to guanine. Considerable evidence is presented to show that a decrease in the intensity of the 1490 cm^?1 Raman band of quanine in DNA is strong indication of a hydrogen bond being attached to the N-7 position of quanine. A specific model is presented for the interaction of the arginine residues with the guanine residues in the major groove of DNA. The Raman frequency of the histone Amide 1 band indicates that these protein molecules have a high α-helical content while the phosphate diester stretch frequency of the DNA shows the DNA to be in the B-family.